Components and Building Blocks Chapter 5. Semiconductor Devices (Materials) Normally made from Silicon (Si) or Germanium (Ge) Atoms of both have 4 electrons.

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Presentation on theme: "Components and Building Blocks Chapter 5. Semiconductor Devices (Materials) Normally made from Silicon (Si) or Germanium (Ge) Atoms of both have 4 electrons."— Presentation transcript:

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Semiconductor Devices (Materials) Normally made from Silicon (Si) or Germanium (Ge) Atoms of both have 4 electrons in their outer layer of shell called valance electrons – These outer 4 electrons are shared with other atoms to form a crystal Crystals of pure Silicon or Germanium are not normally good conductors or insulators

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Semiconductor Devices (Materials) Manufactures add other atoms into the crystals – This is called doping – These atoms are referred to as impurities – The impurities are chosen for there ability to alter the way electrons are shared within the crystal Arsenic (As) and antimony (Sb) examples of impurities – They have five electrons in there outer layer – Adds a free electron to create an N-type material

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Semiconductor Devices (Diodes) A diode allows current flow in one direction and resists current flow in the other direction. There are two terminals – Anode – P-type material – Cathode - N-type material Current flows with a positive connection to the Anode and a negative connection to the Cathode – Current is blocked if the leads are reversed

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Zener Diodes Used as voltage reference and regulators The Zener voltage is the voltage required to cause avalanche – Can safely withstand avalanche current Maintains a stable voltage over a wide current range

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Tunnel Diode No rectifying properties Has negative resistance when properly biased – As voltage increases current decreases Capable of amplification and oscillation Obsolete and not used today

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Varactor Diode (Varicap) Change capacitance by varying the reverse bias – Creates voltage controlled capacitors Range from a few pF to over 100 pF Used in frequency multipliers, tuned circuits and modulators

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Pin Diode Formed by diffusing P-type and N-type layers onto opposite ends of a large almost pure intrinsic material layer. Forward resistance varies inversely with forward DC bias voltage The amount of resistance to RF signals can be changed by changing the forward bias Used as an RF switch or attenuator

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JFET Transistor Has high input impedance compared to Bipolar Transistor Three terminals – Source – Drain – Gate Source and Drain connected by the channel – Voltage change on the gate controls current flow in the channel

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MOSFET Transistor Higher input impedance than JFET Some MOSFETs have two gates with different voltages for special applications Most MOSFETS have built in gate protecting Zener diodes

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Enhancement & Depletion Mode FETs Depletion Mode – Current flows between source and drain when no gate voltage is applied – Gate is reverse biased in operation – Current decreases when reverse bias is applied Enhancement Mode – Requires gate voltage for current to flow between source and gate – Current increases with increase in forward bias

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Liquid-Crystal-Displays Uses crystalline liquid in conjunction with polarizing filters – Becomes opaque when voltage is applied A primary advantage is they consume very little power compared to other display types Slow to operate at low temperatures May be damaged by high temperatures

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Cathode-Ray Tubes An electron beam is accelerated by high voltage and strikes a glass surface coated with a phosphorescent material – Glows when struck – Persistence is the length of time the glow continues after being illuminated by the beam To high of anode voltage will cause the beam to generate X-rays when it strikes the phosphor

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Charge-Coupled Devices Series of stages from the input to the output containing an analog voltage Values transfer from stage to stage when a clock pulse is received. Can not be used as an analog to digital converter

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Digital Logic Basics The output is determined by the simultaneous levels of the inputs Boolean Algebra – Variables only have two values 0 and 1 False or True High or Low – Use truth tables Shows output for all combinations of input

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One-Input Elements Two Elements have a single input – Non-inverting buffer Output same as input – Inverter or NOT Output opposite of input The small circle on the output indicates inversion of the signal

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And & NAND Gate Have two or more inputs Output of AND is 1 only if all inputs are 1 Output of NAND gate is the inverse of the AND gate The NAND gate only has a 0 output when all of the inputs are 1

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OR & NOR Gates The output of the OR gate is 1 if any or all inputs are 1 The + sign is used between variables to show the OR Function – X = A + B The output of the NOR gate is the inverse of the OR gate

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Exclusive OR & NOR Gate The Exclusive OR gate results in a 1 if only one of the inputs is 1 The Exclusive NOR gate results in a 0 if only 1 of the inputs are 1

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Tri-State Logic Allows multiple device outputs to be connected on a single bus Device has a 0, 1 and High Impedance output – Allows only one IC to control the bus at a time – Other ICs are set to High Impedance which puts them in a standby state

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Synchronous Logic Flip-Flops Is a binary sequential-logic element – Has two stable states (bistable) the set state (1 state) The reset state (0 state) – Also know as bistable multivibrator – Can store 1 bit There are normally two outputs (Q & Q not) – If Q = 1 than Q not = 0 – If Q = 0 than Q not = 1

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Synchronous vs Asyncronous Synchronous flip-flops – Require a clock – Only change state if there is a clock signal – Also called clocked, clock-driven, or gated flip- flops Asynchronous flip-flops – Independent of clock – Output changes whenever the input changes – Also called unclocked or data-driven

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R-S Flip-flop Inputs are Set and Reset If S and R are both 0 the output is the same as the last state change

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Clocked R-S Flip-Flop Has an additional pin for the clock signal No change in the output state can happen until a clock pulse is received

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D Flip-Flop The Q output takes the value of the D input when the clock signal triggers the flip-flop

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T Flip-Flop The output of a bistable T flip-flop changes state two times for every two trigger pulses The bistable flip-flop divides the input signal by two Two flip-flops can be used to divide the signal by 4

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J-K Flip-Flop If J & K are at opposite states Q takes the value of J when the clock signal triggers the FF If J & K are both 0 the output does not change when the clock triggers If J & K are both 1 the clock trigger toggles the Q output

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One-Shot or Monostable Multivibrator Switches momentarily to the opposite binary state and then returns after a set time to its original state – Generates one pulse with each trigger – Pulse length determined by R-C circuit T= 1.1RC

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Divide by N counter A series of flip-flops connect so one output pulse occurs after every N pulses Each flip-flop divides by 2 Most counters have the ability to clear to 0 Counters can count up or down A decade counter divides by 10 – One output pulse for every 10 input pulses

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Frequency Counter A frequency counter is one of the most accurate ways to measure a frequency – Counts number of pulses during a specific interval and displays results – Gives a digital representation of the frequency of a signal – Accuracy depends on an internal crystal controlled oscillator or time base

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Very Low Frequency Counting Alternate method of determining frequency – Used for very low frequency – Measure the period of a signal and mathematically compute the frequency – Much faster than counting slow pulses Gives improved resolution of low frequency signals within a comparable time period

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Prescaler For high frequencies a prescaler is used ahead of a lower frequency counter – Reduces the frequency by a factor of 10, 100, 1000 or other integer divisor

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Marker Generators A high stability crystal oscillator that generates a series of reference signals – Used to calibrate a receivers frequency setting – Can use a 100 kHz oscillator Use two flip-flops to divide to 50 and 25 kHz – Allows markers at the band edges as well as most license class and emission restrictions

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Logic Families - TTL Transistor-transistor logic (TTL) – One of the oldest – Made entirely of bipolar transistors – Requires a 5 volt power supply – If inputs are left open they assume a HIGH – Usually identified by 7400/5400 numbering – A high logic is between 2 and 5 volts – A low logic is between 0 and.8 volts

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Logic Families - CMOS Complimentary metal-oxide semiconductor – Composed of N-channel and P-channel FETs Most widely used form of digital logic When a CMOS gate is not switching it draws very little power The switching threshold for CMOS inputs is about half the supply voltage – Gives great immunity to noise

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Optoelectronics Photo Transistor – A transistor in a clear package to allow light to hit the junction – Transistor turns on when exposed to light Can be used as a photo detector

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Optocouplers and Optoisolators An LED and photo transistor sharing the same IC There is no current between the input and output Can be used as a Solid State Relay – Much faster than an electromechanical relay Often used to switch 120 V AC circuits with low power digital circuits

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Optical Shaft Encoder Used to control the frequency of the VFO and other functions in modern radios A device which detects rotation of a control by interrupting a light source with a patterned wheel

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Photovoltaic Cells – Solar Cells Converts light to electrical energy If a PN junction is exposed to light photons will be absorbed by the electrons The voltage developed by a photovoltaic cell depends on the material it is made from – Silicon is the most common material – Silicon develops an open circuit vale of.5 volts The efficiency of a photovoltaic cell is based on the relative fraction of light that is converted to current